KR0123724B1 - Synchronization signal generator and image signal processing device using same - Google Patents

Abstract

A synchronization signal generator and an image signal processing apparatus using the same. The generator includes a reference potential setting circuit for receiving a composite video signal and setting a reference potential, a low band pass filter for removing color carriers, a composite synchronization signal separation circuit for separating the composite synchronization signal, and a vertical synchronization signal. And a pseudo horizontal synchronizing signal generating circuit for generating a pseudo horizontal synchronizing signal.

In addition, the image signal processing apparatus is characterized by digitally converting the sampling clock by using the vertical and pseudo horizontal synchronization signals generated by the generator to increase the reliability of the signal and to prevent screen shaking during screen display. Can be.

Description

Synchronization signal generator and image signal processing device using same

1 is a block diagram illustrating a conventional synchronization signal generator.

2 is a block diagram illustrating a synchronization signal generator according to the present invention.

FIG. 3 is a block diagram illustrating an image signal processing apparatus for sampling and storing a composite image signal according to the present invention using the synchronization signal generator of FIG. 2.

4 is a block diagram illustrating another image signal processing apparatus for screen synthesis and synchronization according to the present invention using the synchronization signal generator of FIG.

The present invention relates to a composite image signal processing apparatus, and to a synchronization signal generator capable of overcoming incompleteness of a horizontal synchronization signal during reproduction or reception by generating a pseudo horizontal synchronization signal from a vertical synchronization signal, and an image signal processing apparatus using the same. will be.

In general, vertical and horizontal synchronization signals are detected from a composite video signal reproduced in video, television, or multimedia to synchronize the display on the screen. However, if the vertical and horizontal synchronization signals are incomplete, the screen may shake up or down or to the left or right of the screen, thereby preventing normal output. Therefore, accurate reproduction is required. Therefore, even in the case of accurate reproduction, there is a defect in the input composite video signal itself. In particular, incompleteness of the horizontal synchronization signal is greater than that of the vertical synchronization signal. This is because the vertical synchronization signal has a large direct current component and is relatively strong to noise. Therefore, the shaking phenomenon of the left and right of the screen is often generated rather than the shaking phenomenon of the screen by the vertical synchronization signal. To learn more in detail, a conventional synchronization signal generating circuit is as follows.

1 is a block diagram for explaining a conventional synchronization signal generating circuit.

The conventional synchronization signal generation circuit of FIG. 1 includes a clamp circuit 1, a low pass filter (LPF) 2, a composite synchronization signal separation circuit 3, an automatic frequency control circuit 10 and a vertical synchronization signal generation circuit 20. It consists of).

First, the color carrier is removed from the complex video signal through the clamp circuit (1) and the LPF (2), and the complex synchronous signal is detected through the complex synchronous signal separation circuit (3) to detect the automatic frequency control circuit (10) and the vertical synchronous signal. It is input to the generation circuit 20. The automatic frequency control circuit 10 includes a phase detection circuit 11, a voltage controlled oscillator 12, and a divider 13 to receive the composite synchronous signal and the output signal of the divider 13 and to detect the phase 11. Compare and detect the phase through the, and move from the oscillation frequency frequently to the frequency of the output signal of the phase detection circuit 32 through the voltage controlled oscillator 12, and receives the output signal of the voltage controlled oscillator 12 and divider ( Through 13), the frequency is divided and output as the final horizontal synchronous signal.

Therefore, the conventional synchronization signal generation circuit has a problem that the screen shake occurs when the synchronization signal from outside or reproduced is incomplete, especially when the horizontal synchronization signal is incomplete.

Accordingly, an object of the present invention is to provide a synchronization signal generator capable of generating a horizontal synchronization signal directly from a vertical synchronization signal resistant to noise to prevent screen shaking.

Another object of the present invention is to provide an image signal processing apparatus for sampling and storing a composite image signal using a synchronization signal generator.

Another object of the present invention is to provide another image signal processing apparatus for synthesizing and synchronizing a screen using a synchronization signal generator.

In order to achieve the above object, a synchronization signal processing apparatus according to the present invention includes a reference potential setting means for setting a reference potential by receiving a composite video signal and an output signal of the reference potential setting means for removing a color carrier. A composite synchronous signal separating means for separating a composite synchronous signal by receiving a low band pass filter, an output signal of the low band pass filter, and receiving a vertical synchronous signal in response to an fsc signal of a predetermined multiple by receiving the composite synchronous signal. And vertical pseudo signal separating means for separating and pseudo horizontal synchronizing signal generating means for generating a pseudo horizontal synchronizing signal in response to the vertical synchronizing signal and the predetermined multiple fsc signal.

In addition, the video signal processing apparatus according to the present invention in order to achieve the above-mentioned other object is a reference potential setting means for setting a reference potential by receiving a composite video signal, and the output signal of the reference potential setting means receives a color carrier A low band pass filter for removing the signal, a compound synchronous signal separating means for separating the synchronous signal by receiving the output signal of the filter, and a vertical synchronous signal in response to the fsc signal of a predetermined multiple by receiving the compound synchronous signal. A vertical synchronous signal separating means for separating, a pseudo horizontal synchronous signal generating means for generating a pseudo horizontal synchronous signal in response to the vertical synchronous signal and the predetermined multiple fsc signal, and converting the composite video signal into a digital signal; Analog / digital conversion means, and the analog / digital signal in response to the vertical synchronization signal and the pseudo horizontal synchronization signal. It characterized in that it includes a timing control signal generating means for supplying a sampling clock to de-converting means.

According to another aspect of the present invention, there is provided an apparatus for processing another video signal according to the present invention, comprising: first reference potential setting means for receiving a first composite video signal and setting a reference potential, and an output signal of the first reference potential setting means; A first low band pass filter for removing a color subcarrier, a first compound synchronous signal separating means for separating a first compound synchronous signal by receiving an output signal of the first low band pass filter, and the first low band pass filter; A first vertical synchronous signal separating means for receiving a first multiple synchronous signal and separating a first vertical synchronous signal in response to an fsc signal of a predetermined multiple; a first vertical synchronous signal and a first multiple of the fsc signal in response to the predetermined multiple fsc signal; First pseudo horizontal synchronizing signal generating means for generating a pseudo horizontal synchronizing signal, second reference potential setting means for setting a reference potential by receiving a second composite video signal, and outputting of the second reference potential setting means A second low band pass filter for receiving a signal and removing a color subcarrier, a second compound synchronization signal separating means for separating a second composite synchronization signal by receiving an output signal of the second low band pass filter, and Second vertical synchronous signal separation means for receiving a second multiple synchronous signal and separating a second vertical synchronous signal in response to the predetermined multiple fsc signal; and in response to the second vertical synchronous signal and the predetermined multiple fsc signal. Second horizontal horizontal synchronization signal generation means for generating a second horizontal horizontal synchronization signal, analog / digital conversion means for converting the second composite video signal into a digital signal, storage means for storing the converted digital signal, and Digital / analog converting means for converting the stored digital signal into an analog signal, synthesizing means for receiving the first composite video signal and synthesizing the converted analog signal; Supplying a sampling clock to the analog / digital converting means, supplying a read / write signal to the storage means in response to the first vertical synchronizing signal and the first pseudo horizontal synchronizing signal, and supplying the read / write signal to the storage means. And timing control signal generating means for supplying a control signal to the synthesizer in response to the second pseudo horizontal synchronizing signal.

Hereinafter, with reference to the accompanying drawings will be described in detail the present invention.

2 is a block diagram illustrating a synchronization signal generator according to the present invention.

The synchronization signal generator according to the present invention of FIG. 2 includes a clamp circuit 30, a low pass filter (LPF) 40, a composite synchronous signal separation circuit 50, a vertical synchronous signal generation circuit 60, It consists of a pseudo horizontal synchronizing signal generating circuit 70.

First, the composite video signal is applied to the clamp circuit 30 through the input terminal 25. At this time, the clamp circuit 30 sets the reference potential of the threshold voltage of the composite synchronous signal separation circuit 50 to stably separate the composite video signal. Subsequently, the LPF 40 refers to a filter for removing the color carrier component from the composite video signal. Subsequently, the composite synchronous signal separation circuit 50 separates only the composite synchronous signal at the synchronous separation threshold level based on the reference potential. Subsequently, the vertical synchronous signal generating circuit 60 receives the output signal of the composite synchronous signal separation circuit 50 to generate a vertical synchronous signal. Subsequently, the pseudo horizontal synchronous signal generation circuit 70 receives the vertical synchronous signal as a reset signal and generates a pseudo horizontal synchronous signal using a 4fsc (Color Sub-Sync) signal as a clock signal. At this time, the generated pseudo horizontal synchronizing signal becomes a horizontal synchronizing signal that is exactly the same every H (horizontal synchronizing period).

3 is a block diagram illustrating an image signal processing apparatus for sampling and storing a composite image signal using the synchronization signal generator of FIG. 2 according to the present invention.

The video signal processing apparatus according to the present invention of FIG. 3 is composed of the synchronization signal generator 100, the A / D converter 80, the memory 85, and the timing control signal generator 90 of FIG.

First, a vertical sync signal and a pseudo horizontal sync signal are generated from the composite video signal through the sync signal generator 100 of FIG. Subsequently, the timing control signal generator 90 receives the vertical synchronization signal and the pseudo horizontal synchronization signal to generate a control signal for controlling the A / D converter 80 and the memory 85, respectively.

The A / D converter 80 receives a composite video signal and converts it into a digital signal. At this time, the sampling clock of the A / D converter 80 is determined by the timing control signal generated by the timing control signal generator 90. The memory 85 also stores a digitally converted signal input through the A / D converter 80 in response to the read / write signal from the timing control signal generator 90. Therefore, in sampling and storing the composite video signal, the vertical synchronous signal which is less affected by noise without detecting and using the composite synchronous signal included in the general composite video signal is detected from the composite video signal and the horizontal synchronous signal generated through the composite video signal. By using, digitally converted data of the composite video signal can be accurately sampled and stored.

4 is a block diagram illustrating an image signal processing apparatus for screen synthesis and synchronization using the synchronization signal generator of FIG. 2 according to the present invention.

The other image signal processing apparatus of FIG. 4 includes the synchronization signal generators 100A and 100B, the A / D converter 110, the memory 120, and the D / A of FIG. 2 that receive the first and second composite video signals, respectively. The converter 130, the synthesizer 140 and the timing control signal generator 150 is composed of.

The first and second composite video signals generate a vertical synchronization signal and a pseudo horizontal synchronization signal through the same synchronization signal generators 100A and 100B as in the synchronization signal generator of FIG. The timing control signal generator 150 receives the vertical synchronization signal and the pseudo horizontal synchronization signal generated through the synchronization signal generators 100A and 100B to the A / D converter 110, the memory 120, and the synthesizer 140. A timing control signal is generated according to each of the synchronization signals. The A / D converter 110 receives the composite video signal, converts it into a digital signal, and outputs the digital signal to the memory 120. At this time, the A / D converter 110 receives the digitally converted signal in response to the timing control signal as a read / write signal from the timing control signal generator 150 to store and output the sampling clock. do.

Subsequently, the D / A converter 130 receives a digital signal from the memory 120 and converts it into an analog signal. Subsequently, the synthesizer 140 responds to the timing control signal generated from the timing control signal generator 150 in accordance with the vertical and pseudo horizontal synchronization signals generated from the synchronization signal generator 100A. The analog signal generated from the A converter 130 is synthesized and output through the output terminal 145. In this case, the signal output through the output terminal 145 is applied to the screen display device, in particular, the TV is displayed by combining the screen through the first composite video signal and the screen through the second composite video signal.

As described above, the horizontal synchronous signal detected from the composite video signal is more affected by noise than the vertical synchronous signal due to its characteristics. Therefore, the synchronization signal generating apparatus according to the present invention can greatly reduce the shaking of the screen due to weak electric field or signal loss or noise by generating the horizontal synchronization signal from the vertical synchronization signal. In addition, the video signal processing apparatus for sampling and storing the composite video signal using the synchronization signal generator according to the present invention improves the characteristics of the incomplete horizontal synchronization signal by the synchronization signal generator according to the present invention and stores it through accurate sampling. This can improve the reliability of the stored data. In addition, another image signal processing apparatus for screen synthesis and storage according to the present invention has an effect that can achieve accurate screen synchronization while preventing screen shaking in synthesizing screens.

Claims (4)

Reference potential setting means for receiving a composite video signal and setting a reference potential; A low band pass filter for removing the color carrier by receiving the output signal of the reference potential setting means; A composite synchronous signal separating means for receiving the output signal of the low band pass filter and separating the composite synchronous signal; Vertical synchronous signal separation means for receiving the composite synchronous signal and separating the vertical synchronous signal in response to an fsc signal of a predetermined multiple; And a pseudo horizontal synchronizing signal generating means for generating a pseudo horizontal synchronizing signal in response to the vertical synchronizing signal and the predetermined multiple fsc signal. Reference potential setting means for receiving a composite video signal and setting a reference potential; A low band pass filter for removing the color carrier by receiving the output signal of the reference potential setting means; A composite synchronous signal separating means for receiving the output signal of the filter and separating the composite synchronous signal; Vertical synchronous signal separation means for receiving the composite synchronous signal and separating the vertical synchronous signal in response to an fsc signal of a predetermined multiple; Pseudo horizontal synchronizing signal generating means for generating a pseudo horizontal synchronizing signal in response to the vertical synchronizing signal and the predetermined multiple fsc signal; An analog / digital converting means for receiving the composite video signal and converting the composite video signal into a digital signal; And timing control signal generating means for supplying a sampling clock to the analog / digital converting means in response to the vertical synchronizing signal and the pseudo horizontal synchronizing signal. The image signal processing apparatus according to claim 2, further comprising a storage means for receiving the digitally converted signal and storing the digitally converted signal and receiving a read / write signal from the timing control signal generating means. First reference potential setting means for receiving a first composite video signal and setting a reference potential; A first low band pass filter configured to receive an output signal of the first reference potential setting means and to remove a color carrier; First combined synchronous signal separation means for receiving the output signal of the first low band pass filter and separating the first combined synchronous signal; First vertical synchronous signal separation means for receiving the first composite synchronous signal and separating a first vertical synchronous signal in response to an fsc signal of a predetermined multiple; First pseudo horizontal synchronizing signal generating means for generating a first pseudo horizontal synchronizing signal in response to the first vertical synchronizing signal and the predetermined multiple fsc signal; Second reference potential setting means for receiving a second composite video signal and setting a reference potential; A second low band pass filter configured to receive the output signal of the second reference potential setting means and to remove the color carrier; Second combined synchronous signal separation means for receiving an output signal of the second low band pass filter to separate a second combined synchronous signal; Second vertical synchronous signal separation means for receiving the second composite synchronous signal and separating a second vertical synchronous signal in response to the predetermined multiple fsc signal; Second horizontal synchronization signal generation means for generating a second horizontal synchronization signal in response to the second vertical synchronization signal and the predetermined multiple fsc signal; Analog / digital conversion means for converting the second composite video signal into a digital signal; Storage means for storing the converted digital signal; Digital / analog conversion means for converting the stored digital signal into an analog signal; Synthesizing means for receiving the first composite video signal and synthesizing the converted analog signal; A sampling clock is supplied to the analog / digital converting means, a read / write signal is supplied to the storage means in response to the first vertical synchronizing signal and the first pseudo horizontal synchronizing signal, and the second vertical synchronizing signal and the And a timing control signal generating means for supplying a control signal to said synthesizer in response to a second pseudo horizontal synchronizing signal.